I saw the following line of code here in C.

 int mask = ~0;

I have printed the value of mask in C and C++. It always prints -1.

So I do have some questions:

  • Why assigning value ~0 to the mask variable?
  • What is the purpose of ~0?
  • Can we use -1 instead of ~0?
up vote 78 down vote accepted

It's a portable way to set all the binary bits in an integer to 1 bits without having to know how many bits are in the integer on the current architecture.

  • 7
    -1 also sets all the bits in an integer to 1 without knowing the width of int type. It just implies the use of two's complement – phuclv Sep 23 '17 at 6:24
  • 25
    @LưuVĩnhPhúc correct. The ~0 method has fewer dependencies. Works on unsigned, non-two's compliment systems and is (arguably) less cryptic. – Richard Hodges Sep 23 '17 at 7:02
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    @chqrlie why not? BTW using signed values for the bitmasks is a weird idea. – P__J__ Sep 23 '17 at 8:01
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    @PeterJ_01: If long has more bits than int, then ~0u (which has type unsigned) would be zero-extended as part of initializing u. – Henning Makholm Sep 23 '17 at 12:45
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    This is not portable if on one's complement: it gives a negative zero, which a conforming compiler may decide is a trap representation. At that point you have UB. To be fair, such an implementation may be said to not have an all-ones value for int in the first place. – Kevin Sep 23 '17 at 20:46

C and C++ allow 3 different signed integer formats: sign-magnitude, one's complement and two's complement

~0 will produce all-one bits regardless of the sign format the system uses. So it's more portable than -1

You can add the U suffix (i.e. -1U) to generate an all-one bit pattern portably1. However ~0 indicates the intention clearer: invert all the bits in the value 0 whereas -1 will show that a value of minus one is needed, not its binary representation

1 because unsigned operations are always reduced modulo the number that is one greater than the largest value that can be represented by the resulting type

  • The text says that 2's complement 32-bit integer can be assumed – 6502 Sep 23 '17 at 6:27
  • Note that for all unsigned types, u = -1; sets all bits 1. For unsigned types wider than unsigned, u = ~0; and u = -1u; do not. – chux Sep 15 at 14:31

That on a 2's complement platform (that is assumed) gives you -1, but writing -1 directly is forbidden by the rules (only integers 0..255, unary !, ~ and binary &, ^, |, +, << and >> are allowed).

You are studying a coding challenge with a number of restrictions on operators and language constructions to perform given tasks.

The first problem is return the value -1 without the use of the - operator.

On machines that represent negative numbers with two's complement, the value -1 is represented with all bits set to 1, so ~0 evaluates to -1:

 * minusOne - return a value of -1 
 *   Legal ops: ! ~ & ^ | + << >>
 *   Max ops: 2
 *   Rating: 1
int minusOne(void) {
  // ~0 = 111...111 = -1
  return ~0;

Other problems in the file are not always implemented correctly. The second problem, returning a boolean value representing the fact the an int value would fit in a 16 bit signed short has a flaw:

 * fitsShort - return 1 if x can be represented as a 
 *   16-bit, two's complement integer.
 *   Examples: fitsShort(33000) = 0, fitsShort(-32768) = 1
 *   Legal ops: ! ~ & ^ | + << >>
 *   Max ops: 8
 *   Rating: 1
int fitsShort(int x) {
   * after left shift 16 and right shift 16, the left 16 of x is 00000..00 or 111...1111
   * so after shift, if x remains the same, then it means that x can be represent as 16-bit
  return !(((x << 16) >> 16) ^ x); 

Left shifting a negative value or a number whose shifted value is beyond the range of int has undefined behavior, right shifting a negative value is implementation defined, so the above solution is incorrect (although it is probably the expected solution).

Loooong ago this was how you saved memory on extremely limited equipment such as the 1K ZX 80 or ZX 81 computer. In BASIC, you would

Let X = NOT PI

rather than

LET X = 0

Since numbers were stored as 4 byte floating points, the latter takes 2 bytes more than the first NOT PI alternative, where each of NOT and PI takes up a single byte.

  • Not exactly. In those examples all (key)words were encoded by single bytes, as well a the equals sign, variable names and the visible zero itself. However, the numeric constants were followed by (an escape byte?) plus 4-byte floating-point value, which was utilized by the executor but not shown in the source. Hence the size diference here is 3 or even 4 bytes, not 2. – CiaPan Sep 24 '17 at 15:12
  • I should be working ... just did this on some ZX Spectrum emulator and saved it to tape / disk. The first one uses 40 and the seond 35 bytes, so a 5 byte difference. Well, if you have just 1k as on the ZX 81, I guess that is half a percent saving in file size and which is why it was used ... Back to the OP question - would you be able to save a byte or two (or 5) today by using say x = ~0 rather than x = -1? Maybe using a conversion such as long x = ~0 ? – skaak Oct 4 '17 at 12:24
  • I really should be working ... just attempted this in c in a few simple ways but the compiled file was the same size for -1, ~0 and ~(0x00) ... I am sure there are some architectures where this will save a byte or so but such oddities must of course be avoided at all costs nowadays. The compiled files were roughly 8.5k bytes. This would give the poor ZX81 a heart attack ... – skaak Oct 4 '17 at 12:41
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    Modern C compilers are smart enough to recognize ~0 and -1 as the same value. They can also optimize the code either to maximum speed or to minimum size, so you would have to play with compiling options. Furthermore, the compiled code can be rounded up to 4, 8 or 16 bytes for better aligning of functions' entry points, so looking at obj file size is unsuitable for your pusrpose. You might rather compile the C code to assembly, or even disassemble the compiled object module (with some tool like objdump) to see the byte-by-byte representation of your code. – CiaPan Oct 9 '17 at 7:32
  • is there no integer type on those systems? And how can PI be stored in a single byte? – phuclv Jun 30 at 12:36

There are multiple ways of encoding numbers across all computer architectures. When using 2's complement this will always be true:~0 == -1. On the other hand, some computers use 1's complement for encoding negative numbers for which the above example is untrue, because ~0 == -0. Yup, 1s complement has negative zero, and that is why it is not very intuitive.

So to your questions

  • the ~0 is assigned to mask so all the bits in mask are equal 1 -> making mask & sth == sth
  • the ~0 is used to make all bits equal to 1 regardless of the platform used
  • you can use -1 instead of ~0 if you are sure that your computer platform uses 2's complement number encoding

My personal thought - make your code as much platform-independent as you can. The cost is relatively small and the code becomes fail proof

  • Only if the 1s complement implementation supports negative zeros. See also this answer – JHBonarius Sep 24 '17 at 8:05

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